Does Greater Phylogenetic Distance Affect Competition Outcomes in Fungal Communities?
Annette Lewis, Kendall Holcomb, Bárbara Suassuna Schincariol, Josh Stubbs, Geoffery Zahn PhD
Fungi play a critical role in decomposition, affecting nutrient cycling at a global scale. Saprotrophic fungi competitively decompose dead organic matter. However, the role of phylogenetic relatedness on interspecific competition in fungal communities has not received much attention. The theory of phylogenetic over-dispersion suggests that species within a community tend to be less related than expected by chance, therefore limiting competition due to functional redundancy. Similarly, Darwin’s naturalization hypothesis suggests that taxonomically distinct invaders might experience reduced competition and resistance. In this study, we chose three different saprotrophic fungal species with varying relatedness: Aspergillus niger and Fusarium keratoplasticum (from the same family), and Pleurotus ostreatus (from a different phylum). These species were chosen based on decomposition abilities and phylogenetic distances. These species were cultured and placed in seven combinations to assess their ability to decompose and compete as individual fungal populations and as combined communities (e.g., A, B, A+B, B+C, and A+B+C). Each species was placed near a sterilized piece of paper such that competition was evaluated by analyzing the paper coverage in Petri dishes over three weeks. Each Petri dish was analyzed individually based on the average percentage of paper covered and, within combined communities, the percentage of paper each species covered. Interactions between each species and the percentage of the paper covered was recorded for further analysis. Assessing paper coverage allows for the observation of any potential competitive inhibition of decomposition. We hypothesize that decomposing and competitive abilities would be the strongest with A. niger. Despite the fast growth rate of A. niger individually, preliminary results suggest that it was outcompeted when paired with other species. This research highlights the potential nuances in fungal community interactions influenced by phylogenetic relationships, shedding light on the principles of phylogenetic overdispersion and Darwin’s naturalization hypothesis.
We used three saprophytic fungal species Aspergillus niger, Fusarium keratoplasticum, and Pleurotus ostreatus. A. niger and F. keratoplasticum will be purchased from ATCC.org as freeze-dried and frozen samples. P. ostreatus was already available from Dr. Zahn’s laboratory. These fungal species will then be cultured in Petri dishes.
The cultured fungal samples will be placed in 7 combinations to test their ability to decompose as individual fungi populations and combined communities. For each of the combinations, there will be six replicates.
The sterilized paper’s dimensions are: 1in by 1in
Alongside our results, we will obtain genetic information based on the ITS1 gene in GenBank and construct a phylogenetic tree. We will calculate the phylogenetic relatedness of our species via branch length distance, using ape 5.0 in R. This portion of the research will be conducted to observe species’ phylogenetic diversity and decomposition abilities.
Initial phylogenetic tree setup. The sequences were obtained from the NCBI, based on the ITS region, and aligned using the EMBL-EBI’s Multiple Sequence Alignment tool, MUSCLE. This tree has no outgroup selected and serves to show the most basic form of this tree.
Phylogenetic tree rooted on Pericharax heteroraphis, a sea sponge, including species names.
The different combinations we plan to test:
| Species | Combination |
|---|---|
| Aspergillus niger | A |
| Fusarium keratoplasticum | B |
| Pleurotus ostreatus | C |
| Aspergillus niger and Fusarium keratoplasticum | A+B |
| Aspergillus niger and Pleurotus ostreatus | A+C |
| Fusarium keratoplasticum and Pleurotus ostreatus | B+C |
| Aspergillus niger, Fusarium keratoplasticum, and Pleurotus ostreatus | A+B+C |
Main. Compute branch lengths based on our sea sponge, Pleurotus ostreatus. In this, the branch lengths associated with the outgroup are excluded here after using it to root the tree.
| Species | Combination | Branch_Length |
|---|---|---|
| Aspergillus niger | A | 0.4614971 |
| Fusarium keratoplasticum | B | 0.3054016 |
| Pleurotus ostreatus | C | 0.1341214 |
| Aspergillus niger, Fusarium keratoplasticum | A+B | 0.5587292 |
| Aspergillus niger, Pleurotus ostreatus | A+C | 0.5956185 |
| Fusarium keratoplasticum, Pleurotus ostreatus | B+C | 0.4395229 |
| Aspergillus niger, Fusarium keratoplasticum, Pleurotus ostreatus | A+B+C | 0.7969353 |
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 0.1341 0.3725 0.4615 0.4703 0.5772 0.7969
## [1] 0.2126998
General. Below shows the general branch length values where the outgroup’s branch length is kept in the final calculation.
| Species | Combination | Branch_Length |
|---|---|---|
| Aspergillus niger | A | 0.6451528 |
| Fusarium keratoplasticum | B | 0.4890572 |
| Pleurotus ostreatus | C | 0.3177770 |
| Aspergillus niger, Fusarium keratoplasticum | A+B | 0.8464696 |
| Aspergillus niger, Pleurotus ostreatus | A+C | 0.7792742 |
| Fusarium keratoplasticum, Pleurotus ostreatus | B+C | 0.6231786 |
| Aspergillus niger, Fusarium keratoplasticum, Pleurotus ostreatus | A+B+C | 0.9805910 |
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 0.3178 0.5561 0.6452 0.6688 0.8129 0.9806
## [1] 0.2232897
Our plan will be to stick with this one as the branch lengths here have a slightly larger standard deviation, but this difference is negligible
This project will be continued, I will add updates when possible!
General Results:
Non plotly graph (showing same thing)
NOTE: This will be compared to the actual experimental setup.
Another line plot, not including individual species
Alphabetical
Bond Length
This one needs fixing (it’s set up by date)
Alphabetical
Bond Length
Alphabet
Bond length
Scatterplot showing that there seems to be no relationship with total coverage:
Look through this please: